Golf course irrigation water monitoring and treatment system

ABSTRACT

The present invention is process for irrigation of a golf course, which involves monitoring reclaimed water, and treating it when necessary to avoid harmful effects to plantlife. The reclaimed water is tested with a plurality of monitors to obtain results for water quality characteristics, including: total organic carbon compounds; pH; residual chlorine; chlorides; and, sodium. These results are inputted to a computerized data handling system for data collection, storage and analysis for comparison to predetermined acceptable ranges for water quality characteristic, and to show any deviation from said acceptable ranges. Either alarms are set off or treatment occurs or both, when deviations are observed. Treatment includes a dechlorination system and an oxidation system to correct active chlorine and total organic compound levels, respectively. Other important monitors may be included for one or more of the following: hardness; turbidity; alkalinity; conductivity and nitrates.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to irrigation of man-made landscaped and/or agricultural areas, such as parklands, playing fields, farmland for produce or flowers, and especially for golf courses. It is particularly useful for these areas when using reclaimed water. More specifically, the invention is a process for monitoring and treating reclaimed water to use reclaimed water efficiently and without harmful effects from undesirable constituents for the aforesaid irrigation purposes. It includes monitoring numerous water quality characteristics and when predetermined acceptable parameter ranges see deviations, signaling alarms and/or treating the undesirable condition with dechlorination. It also includes an oxidation system for continuous or continual operation.

2. Information Disclosure Statement

The following patents are representative of the state of the art with respect to various teachings relating to water treatment:

U.S. Pat. No. 6,214,607 describes a new method of treating water to remove perchlorate contaminant is disclosed. Water is fed through a filter bed containing perchlorate-reducing microorganisms. The microorganisms reduce the perchlorate, thereby decontaminating the water. An oxidizable substrate serves as an electron donor to the microorganisms. The invention results in safe to undetectable levels of perchlorate in the treated water.

U.S. Pat. No. 6,200,466 describes a reactor system for decontamination of water by photolytic oxidation utilizing near blackbody radiation, the system comprising (1) a reaction chamber defining an internal space with an inlet and an outlet; and (2) a broadband radiator for generating radiant energy with wavelengths between about 150 nm and about 3 um, the broadband radiator disposed within the reaction chamber, such that a sufficient dosage of broadband radiation irradiates the contaminants and/or the oxidant within the internal space of the reaction chamber thereby causing photolytic oxidation of the contaminants by direct action of the radiation on the contaminants to break chemical bonds by sustaining a free radical chain reaction of oxidizing components, thus breaking down the contaminants by way of atomic abstraction of the components of the contaminants. In preferred embodiments, at least a portion of the radiant energy is generated in a pulsed node, such as between about 1 and 500 pulses per second. In preferred embodiments, the broadband radiator generates radiant energy at a rate of between about 1 kW and about 10 MN., and the resultant dosage rate of broadband radiation is between 1 joule/cm2. In preferred embodiments, the radiant energy is produced by at least one gas filled flashlamp having a gas plasma temperature of between about 9,500 K and about 20,000 K.

U.S. Pat. No. 6,136,186 describes a method and apparatus for mineralizing organic contaminants in water or air provides photochemical oxidation in a two-phase boundary system formed in the pores of a TiO2 membrane in a photocatalytic reactor. In the three-phase system, gaseous (liquid) oxidant, liquid (gaseous) contaminant, and solid semiconductor photocatalyst meet and engage in an efficient oxidation reaction, The porous membrane has pores which have a region wherein the meniscus of the liquid varies from the molecular diameter if water to the of a capillary tube resulting in a diffusing layer that is several orders of magnitude smaller than the closest known reactors. The photocatalytic reactor operates effectively at temperature and low pressures. A packed-bed photocatalyst coated particles is also provided.

U.S. Pat. No. 6,132,138 describes a gray water recycling invention that utilizes filtered gray water for maintaining constant moisture levels in building foundations and for other irrigation uses. It allows for the mixture of pesticides with a gray water stream injected under a building in order to treat for insects. Additionally, pesticides, fungicides or fertilizers can be injected into a gray water stream prior to its application in landscape irrigating. This invention has application in single residence and fill development real estate settings.

U.S. Pat. No. 6,117,335 describes a reactor system for decontamination of water by photolytic oxidation utilizing near blackbody radiation, the system comprising (1) a reaction chamber defining an internal space with an inlet and an outlet; and (2) a broadband radiator for generating radiant energy with wavelengths between 150 nm and about 3 μm, the broadband radiator disposed within the reaction chamber, such that a sufficient dosage of broadband radiation irradiates the contaminants and/or the oxidant within the internal space of the reaction chamber thereby causing photolytic oxidation of the contaminants by way of atomic abstraction of the components of the contaminants. In preferred embodiments, at least a portion of the radiant energy is generated in a pulsed mood, such as between 1 and about 500 pulses per second. In preferred embodiments, the broadband radiator generates radiant energy at a rate of between about 1 kW and about 10 MW., and the resultant dosage rate of broadband radiation is between 1 joule/cm² and about 5000 joules/cm². In preferred embodiments, the radiant energy is produced by at least one gas filled flashlamp having a gas plasma temperature of between 9,500° K. and about 20,000° K.

U.S. Pat. No. 5,975,800 relates to a method for treating groundwater in situ in rock or soil. An elongate permeable upgradient zone and an elongate permeable downgradient zone, each in hydraulic communication with a permeable subsurface treatment zone and having a major axis parallel to a non-zero component of the general flow direction, are provided in the subsurface by any of a number of construction methods. The upgradient zone, downgradient zone, and treatment zone are situated within the subsurface medium and have permeabilities substantially greater than the adjacent subsurface medium's permeability. Groundwater is allowed to move from the subsurface medium adjacent to the upgradient zone into the upgradient zone, where the groundwater refracts and moves to a treatment zone by an in situ treatment process, such as a process employing air sparging, sorption or reaction with zero-valent iron, the groundwater moves into, through and out of the downgradient zone into the subsurface medium adjacent to the downgradient zone. The method does not require pumping. A method for directing groundwater around a particular location to prevent contamination of the groundwater by a contaminant located at the particular location, to prevent migration of a contaminant located at a particular location, to reduce the flow velocity of groundwater in the particular location, or to increase the residence time in an in situ treatment center located downgradient from the particular location is also disclosed.

U.S. Pat. No. 5,958,241 describes a method and a system for the treatment of organic hazardous wastes from plant waste and associated wastewater treatment processes, whereby the waste is either introduced directly, or continuously separated from wastewater, and routed to a bioreactor, and whereby no organic solids are generated for further offsite disposal. The system disclosed includes a bioreactor, containing selected bacteria, untreated sludges, and recirculated biomass, and a liquid/solid separator allowing water to be utilized elsewhere in the system and returning solids to the bioreactor. The biodegradation process, initiated continuously, converts hazardous organic constituents in waste stream and wastewater sludges from plant operations to inert materials, for extensive periods of operation, without the need for solids removal, external solids treatment or disposal.

U.S. Pat. No. 5,893,975 treats a variety of flowing wastewater effluents, provides pre-treatment clog-reducing wastewater sludge disintegration, and adds pretreatment nutrients to wastewater so as to enhance microbial growth therein for improving the effectiveness and efficiency of wastewater treatment. The constructed wetland includes a wastewater treatment system having a flow intake, a pre-treatment nutrient addition chamber, and a wastewater flow divider. The flow divider further has a compressed air aerator in the bottom thereof The constructed wetland includes one or more treatment cells having a soil, fine stone, organic and/or synthetic material substrate cap covering a further substrate media accommodating the wastewater to be treated. The substrate cap is populated by natural plants having root systems extend from the substrate downward into the wastewater being treated, and the roots serve to physically and/or biologically mediate the removal of undesirable components from the wastewater. The constructed wetland includes a treated water discharge conduit for discharging the flowing water into a desired after treatment water utilization modality, such as to discharge to the ground or to a body of water.

U.S. Pat. No. 5,863,433 relates to the design and operation of paired subsurface flow constructed wetlands in which significant improvements in wastewater treatment are possible. These improvements are brought about by coupling paired subsurface flow wetlands and using reciprocation, whereby adjacent cells are sequentially and recurrently drained and filled using either gravity, mechanical pumps, U-tube air-lifts and/or a combination thereof This fill and drain technique turns the entire wetland area into a biological reactor, complete with anoxic, anaerobic environments. The frequency, depth and duration of the fill and drain cycle can be adjusted to control redox conditions for specific biologically mediated reactions including, but not limited to, nitrification, denitrification, sulfate reduction, and methanogenesis. Emissions of noxious gases such as hydrogen sulfide and methane can be minimized. Furthermore, by allowing cells to fill to above the level of the substrate by approximately 2 to 4 inches on the fill cycle, it is possible to enhance algae photosynthesis, increase pH, and facilitate photo-oxidative reactions.

U.S. Pat. No. 5,792,336 describes a two stages electrocatalytic method for oxidative-purification of wastewater from soluble substances, such as toxic chemical admixtures difficult of oxidation, including dye-stuffs, detergents, phenols, cyanides and the like, which stages inactivate the soluble substances present in the wastewater in a synergistic fashion and, therefore, are highly efficient, the method comprising the steps of (a) in a first stage, electrochemically treating the wastewater in the presence of chlorine ions, such that chlorine-containing oxidizing agents are formed and at least partially oxidize the soluble substances in the wastewater; and (b) in a second stage, catalytically treating the first stage treated wastewater in presence of a non-chlorine oxidizing agent and an added catalyst, such that remains of the soluble substances are further oxidized, and such that the chlorine-containing oxidizing agents formed during the first stage are catalytically reduced; wherein, the first stage and the second stage act synergistically to purify the wastewater from the soluble substances.

U.S. Pat. No. 4,867,192 describes an automatically controlled irrigation water pH amendment system and apparatus associated with golf courses utilizing automatic irrigation system to irrigate the various species of turf grasses used on fairways, tees, greens and other areas; being adapted to receive an operator pre-selected program of desired irrigation water pH value; to monitor the delivered pH value of the irrigation water and automatically blend into the irrigation water in the flow circuit between the discharge of the irrigation pump station pumps and the pH monitoring point the proper amount of chemical additive to amend-raise or lower-the pH of the delivered irrigation water. The desideratum is a uniformly blended mixture of liquid acid or base chemical with irrigation water to maintain a solution of the water pH value desired by the operator to promote proper agronomic practice in the maintenance of the turf grasses. This objective has been found to be obtainable by causing the two liquids to be blended in the proper ratios through the use of an acid tank, pH sensing probe, sulfuric acid injector pumps, acid manifold, booster pump, flow velocity measuring device, and a solid-state electrical programmable controller; connected to the upstream and downstream ports of an ordinary pressure sustaining valve or differential pressure orifice device as used in the discharge line of a golf course pumping station.

Notwithstanding the prior art, the present invention is neither taught nor rendered obvious thereby.

SUMMARY OF THE INVENTION

The present invention is a process for the irrigation of man-made landscaped areas, and especially golf course greenery, utilizing reclaimed wastewater. In the process, a source or supply of reclaimed water is procured which is selected from the group consisting of treated sewage wastewater, untreated sewage wastewater and natural water supply water containing sewage wastewater. The reclaimed water is subjected to a plurality of monitors for testing to obtain a plurality of test results for water quality characteristics, including: (i) total organic carbon compounds; (ii) pH; (iii) residual chlorine; (iv) chlorides; and (v) sodium. These monitors are sometimes referred to as analyzers, and the two terms are used herein interchangeably. The test results or analyzer results are inputted to a computerized data handling system for data collection, storage and analysis and for comparison to predetermined acceptable ranges for each of the aforesaid water quality characteristics.

Feedback is provided to show any water quality characteristic deviating from predetermined acceptable ranges that effect signaling and/or treatment. Feedback is also provided to enable a maintenance keeper or other grounds personnel or service to determine fertilization requirements.

The reclaimed water is then passed through a dechlorination system and an oxidation system (in any order).

The dechlorination system is for treating the reclaimed water with a dechlorination agent to maintain a level of residual chlorine below a predetermined maximum of a predetermined acceptable range, and is activated in response to feedback from the computerized data handling system when showing deviation from the predetermined acceptable range for residual chlorine.

The oxidation system is for treating the reclaimed water with an oxidizing agent to maintain a level of organic compounds below a predetermined maximum of the predetermined acceptable range. In essence, the oxidizing system is used to destroy undesirable organics, including biological organisms, herbicides and pesticides. It is activated on a continuous or continual basis and could be adjusted by appropriate personnel in response to feedback from the computerized data handling system when showing deviation from the predetermined acceptable range for total organic carbon compounds. In preferred embodiments, it is run on a continuous basis automatically.

The resulting treated reclaimed water is next used to irrigate a golf course area, unless there is a deviation from one of the water quality characteristics being monitored which causes an alarm to signal, in which cause personnel will shut down the irrigation and take corrective measures, such as by-pass, treat, hold or recycle.

The predetermined acceptable ranges are set in accordance with safe use conditions prescribed or desired by the user. In some preferred embodiments, these characteristic parameters are set within the following ranges:

(i) for total organic carbon compounds, 0 milligrams per liter to 50 milligrams per liter;

(ii) for residual chlorine, 0 milligrams per liter to 1 milligrams per liter;

(iii) for pH, 6 to 8;

(iv) for chloride compounds, 0 milligrams per liter to 70 milligrams per liter; and,

(v) for sodium, 0 milligrams per liter to 70 milligrams per liter.

In some embodiments, the data obtained in the process of the present invention by the computer from the monitors is utilized to provide control and assessment of turf and plant fertilizer needs. Also, the data may be logged and stored to create an historical base and the data may be reviewed or presented to establish water quality trends.

In some preferred embodiments, the process includes at least one additional monitor to obtain test results selected from the group consisting of the following water quality characteristics:

(vi) hardness; (vii) turbidity; (viii) alkalinity; and (ix) conductivity.

In other preferred embodiments, all of these characteristics are included.

In some preferred embodiments, the process predetermined acceptable ranges for the following water quality characteristics are set within the following ranges:

(vi) for hardness, 0 to 200 milligrams of calcium carbonate per liter;

(vii) for turbidity, 0 to 10 nephelometric turbidity units;

(viii) for alkalinity, 0 to 200 milligrams per liter total alkalinity; and

(ix) for conductivity, o to 4000 microSiemens per centimeter.

As mentioned, the process of the present invention computerized data handling system provides feedback to show any water quality characteristic deviation, and the process includes initiating an alarm selected from the group consisting of audio alarms, visual alarms and combinations thereof when selected characteristic deviations occur. Thus, the alarm(s) would signal in response to deviations for TOC, pH, chloride compounds or sodium, and for hardness, alkalinity, turbidity and conductivity when monitors are included for these characteristics. For example, the alarm system may include direct contact alarm signaling to a groundskeeper superintendent or other facility manager.

In the most preferred embodiments of the present invention, the process is one wherein the dechlorination system is a vitamin C dechlorination system wherein vitamin C agent is fed into the reclaimed water in response to the computerized data handling system showing a deviation from the predetermined acceptable range for residual chlorine.

Also, in the most preferred embodiment of the present invention, the process is one wherein the oxidation system is ozone, where in ozone is fed into the reclaimed water at the rate established by the TOC output. In this embodiment hydrogen peroxide is fed at the ozone reactor to further promote oxidation

In some embodiments of the present invention process, a nitrate monitor is included and preferably, the predetermined acceptable ranges for nitrate are set within the range of 0 to 100 milligrams per liter nitrate as nitrogen.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention should be more fully understood when the specification herein is taken in conjunction with the drawings appended hereto wherein:

FIGS. 1 and 2 show schematic diagrams for two embodiments of the present invention golf course irrigation system; and,

FIG. 3 illustrates the required and optional features of the computerized data handling system used in the present invention golf course irrigation system.

DETAILED DESCRIPTION OF THE PRESENT INVENTION

The present invention relates to irrigation of golf course areas to maintain greenery and plantlife. Fairways, greens and surrounding plantlife are more efficiently irrigated with reclaimed or recycled water. Otherwise, irrigation would be prohibitively expensive and would involve inefficient use of precious potable water. Many country clubs and public golf courses utilize reclaimed water to irrigate their facilities. Such reclaimed water is sewage wastewater which has been treated or untreated (as by negligence, accident or defiance of applicable laws and ordinances) and may come from a municipal, county or other government operated or privately operated treatment facility, or may come from a natural water source, such as a stream, river or other water source into which treated and/or untreated sewage wastewater has been dumped. These reclaimed water sources provide essential irrigation water, but sometimes contain undesirable, harmful components, such as biologically harmful nematodes, pesticides, fungicides and other organics, chlorine, excess nitrogen and excessive minerals. These and other water quality characteristics, such as turbidity, pH, alkalinity and hardness, may either cause or be indicative of components, which cause harm and even death to vegetation such as grass and plants. For these reasons, the present invention has been developed to both treat undesirable reclaimed water constituents and/or set of alarm(s) to signal to maintenance to shut down or correct problems before the reclaimed water is used for irrigation. One critical feature of the present invention is to collect data and to establish predetermined acceptable ranges of water quality characteristics within which the reclaimed water must fall or an alarm or treatment or both will occur. Another critical feature is the automatic initiation and control of dechlorination and of oxidation in response to residual chlorine and total organic carbon compound levels, respectively, being outside of predetermined acceptable ranges. In the present invention, the process involves the use of monitors, a computerized data handling system, a dechlorination system and an oxidation system.

Referring now to FIG. 1, there is shown a schematic representation of one embodiment of the present invention. In FIG. 1, reclaimed water form any one or more of the sources mentioned above is piped into a golf course facility via piping 3. A pH monitor 5, a total organic carbon (TOC) monitor 7, a residual chlorine monitor 9 and a sodium monitor 11 are connected to piping 3 for testing/monitoring of those water quality characteristics. The residual chlorine monitor (analyzer) could be two different units or a single unit. However, chloride compound water quality characteristic is used for a shutdown determination, whereas the active chlorine water quality characteristic is used for an automatic interactive treatment, i.e. dechlorination. The aforesaid monitors are electronically connected to computer/data handling system 13 for input thereto of monitor tests results from the reclaimed water stream of piping 3. Alternatively, these monitors (and others described below) could be connected to a holding tank, a pond or other natural waterway or other manmade holding facility, for testing. The details of the functionality of the computer/data handling system 13 are set forth in conjunction with FIG. 3 below. In general, the computer/data handling system (CDHS)13 has three primary objectives: (a) it collects and stores data and retains predetermined acceptable ranges (criteria) for the data and compares the data to the criteria; (b) it sets off one or more alarms 15 when the pH, the residual chloride, TOC compounds or the sodium readings (or other optional water quality characteristics readings described below) deviate from predetermined criteria, i.e., set ranges, such as, hypothetically, 0 to 2500 mg/l or 5 to 7; and (c) it initiates automatic treatment when the residual chlorine or the TOCs exceed acceptable criteria.

Thus, piping 3 is connected to dechlorination system 17 and oxidation system 19 for treatment at the desired times, i.e. as needed, when determined by the computer/data handling system 13. The CDHS 13 receives the data from the monitors and when the TOC characteristic is excessive, it initiates an increased feed in the oxidation system 19; when the residual chlorine is excessive, it initiates the dechlorination system 19. The adjusted (treated) reclaimed water is then sent to a conventional golf course irrigation system 21, such as automatic sprinklers, etc. As an extra precaution, residual chlorine monitoring and pH monitoring are also conducted post-dechlorination and post-oxidation to confirm that levels remain within acceptable ranges after treatment. If these post-treatment monitorings show unacceptable results, then adjustments may be included in the programming, or alarms or shutdowns may be proscribed, depending upon the facilities, system and risk management of the user.

FIG. 2 shows another present invention system with more options and preferred details. Here items identical to those shown in FIG. 1 are identically numbered, and, to the extent that they are not further described her, function as described here conjunction with FIG. 1 above. In FIG. 2, additional monitors have been included. These are hardness monitor 23, alkalinity monitor 25, conductivity monitor 27 and turbidity monitor 29. They are connected to the piping 3 for reclaimed water analysis and, when excessive are alarm initiation water quality characteristics. All of these monitors, any one of these or any combination of these could be included within the scope of the present invent, and FIG. 2 represents only one preferred embodiment.

In FIG. 2, the dechlorination system is specified as Vitamin C dechlorination, and this is clearly the preferred dechlorination agent. An optional holding pond 31 for storage is also shown downstream from the treatment stage, and upstream from the actual irrigation. In this embodiment, the reclaimed, monitored and treated, as needed water is stored until needed.

Referring to FIG. 3, the diagram shows the details of the computerized data handling system 51, illustrating required functions 53 and optional functions 55.

EXAMPLE

The system of the present invention shown in FIG. 2 with the functions shown in FIG. 3 is deployed at a privately owned golf course utilizing ponded (lagooned) municipal wastewater and storm water runoff for the reclaimed water. The municipal wastewater undergoes primary and secondary sludge wastewater treatment before ponding.

The following monitors are included:

(1) TOC Monitor—an OptiQuant (TM of Hach Company) UV Organic Analyzer, utilizes reagent free ultraviolet probe with turbidity compensation, translates spectral absorbance coefficient to three different organic values, chemical oxygen demand (COD), biological oxygen demand (BOD) and total organic compounds (TOC). It is turned off and on in a timed sequence by the CDHS, as are all monitors in this example.

(2) pH Monitor—EC 310 Model from Hach Company, measures full range from) 1 to 14.

(3) Hardness Monitor—SP 510 Harness Monitor from Hach Company, measures hardness expressed as ppm, and as mg calcium carbonate per liter.

(4) Alkalinity Monitor—APA Alkalinity Process Analyzer from Hach Company, measures total alkalinity as ppm.

(5) Conductivity Monitor—Model 9782 Conductivity Analyzer from Honeywell Company, measures micromhos and megohms per cm

(6) Turbidity Monitor—Model 1720D Turbidimeter from Hach Company, measure turbidity in nephelometric turbidity units (NTU), with a 0 to 100 range and 0.001 resolution.

(7) Chloride compound/active chlorine Monitor—Model CL17 Chlorine Analyzer from Hach Company, measures free (active) chlorine and total chlorine content, range of 0 to 5 mg per liter.

(8) Sodium Monitor—HACH Model 9073 Sodium Analyzer measures soluble sodium, range of 0 to 10,000 ppm.

(9) Nitrate Monitor—APA 6000 Nitrate Analyzer measures soluble nitrates a nitrogen in mg per liter, ppm and ppb.

The system includes post treatment ponding and a conventional irrigation system. As the reclaimed monitor is piped into the system, all of the monitors, either periodically or by preprogrammed schedule, or in some cases, continuously monitor the system. As the reclaimed water passes through with all water quality characteristics measuring within predetermined ranges, the water is simply fed to the holding pond as needed. When the residual chlorine exceeds the desired range, the dechlorination system is initiated and will run until the readings fall within the acceptable range. As a precaution, post treatment readings are also taken and, if unfavorable, the computer may increase treatment, signal an alarm, shutdown the flow or some combination thereof Likewise, when the TOC exceeds its acceptable range, the oxidation system feed rate will be adjusted to increase dosage until the TOC readings fall back into the acceptable range. When any one or more of the other monitored water quality characteristics exceed their acceptable ranges, either an alarm will signal and/or a shutdown will occur. The system results in the avoidance of harmful factors being entered into the irrigation system and damaged and/or destroyed plantlife is eliminated.

Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein. 

What is claimed is:
 1. A process for irrigation of man-made landscaped areas, which comprises: (a) procuring a supply of reclaimed water selected from the group consisting of treated sewage wastewater, untreated sewage wastewater and natural water supply water containing sewage wastewater; (b) subjecting said reclaimed water to a plurality of monitors and testing said reclaimed water with said plurality of monitors to obtain a plurality of test results for water quality characteristics, including: (i) total organic carbon compounds; (ii) pH; (iii) residual chlorine; (iv) chlorides; and, (v) sodium; (c) inputting said test results to a computerized data handling system for data collection, storage and analysis for comparison to predetermined acceptable ranges for each of said water quality characteristics, and providing feedback to show any water quality characteristic deviating from said acceptable ranges; (d) providing a dechlorination system to said reclaimed water for treating said reclaimed water with a dechlorination agent to maintain a level of residual chlorine below a predetermined maximum of said predetermined acceptable range, and activating said dechlorination system in response to feedback from said computerized data handling system when showing deviation from said predetermined acceptable range for residual chlorine; (e) providing an oxidation system to said reclaimed water for treating said reclaimed water with an oxidizing agent to maintain a level of total organic compounds below a predetermined maximum of said predetermined acceptable range, and controlling said oxidation system in response to feedback from said computerized data handling system when showing deviation from said predetermined acceptable range for total organic carbon compounds; and (f) irrigating a man-made landscaped area with reclaimed water which has been processed in accordance with the preceding steps.
 2. The process of claim 1 wherein said plurality of monitors includes at least one additional monitor to obtain test results selected from the group consisting of the following water quality characteristics: (a) hardness; (b) turbidity; (c) alkalinity; and (d) conductivity.
 3. The process of claim 2 wherein said plurality of monitors includes additional monitors to obtain test results for the following water quality characteristics: (e) hardness; (f) turbidity; (g) alkalinity; and (h) conductivity.
 4. The process of claim 1 wherein said providing feedback to show any water quality characteristic deviation includes initiating an alarm selected from the group consisting of audio alarms, visual alarms and combinations thereof.
 5. The process of claim 4 wherein said alarm is initiated in response to feedback showing any deviation from water quality characteristics selected from the group consisting of pH, chloride compounds and sodium.
 6. The process of claim 2 wherein said providing feedback to show any water quality characteristic deviation includes initiating an alarm selected from the group consisting of audio alarms, visual alarms and combinations thereof.
 7. The process of claim 6 wherein said alarm is initiated in response to feedback showing any deviation from water quality characteristics selected from the group consisting of pH, chloride compounds, sodium, hardness, turbidity, alkalinity and conductivity.
 8. The process of claim 1 wherein said dechlorination system is a vitamin C dechlorination system wherein vitamin C is fed into said reclaimed water in response to said computerized data handling system showing a deviation from said predetermined acceptable range for active chlorine.
 9. A process for irrigation of a golf course, which comprises: (a) procuring a supply of reclaimed water selected from the group consisting of treated sewage wastewater, untreated sewage wastewater and natural water supply water containing sewage wastewater; (b) subjecting said reclaimed water to a plurality of monitors and testing said reclaimed water with said plurality of monitors to obtain a plurality of test results for water quality characteristics, including: (i) total organic carbon compounds; (ii) pH; (iii) residual chlorine; (iv) chlorides; and, (v) sodium; (c) inputting said test results to a computerized data handling system for data collection, storage and analysis for comparison to predetermined acceptable ranges for each of said water quality characteristics, and providing feedback to show any water quality characteristic deviating from said acceptable ranges; (d) providing a dechlorination system to said reclaimed water for treating said reclaimed water with a dechlorination agent to maintain a level of active chlorine below a predetermined maximum of said predetermined acceptable range, and activating said dechlorination system in response to feedback from said computerized data handling system when showing deviation from said predetermined acceptable range for active chlorine; (e) providing an oxidation system to said reclaimed water for treating said reclaimed water with an oxidizing agent to maintain a level of total organic compounds below a predetermined maximum of said predetermined acceptable range and to destroy biological hazards, and controlling said oxidation system in response to feedback from said computerized data handling system when showing deviation from said predetermined acceptable range for total organic carbon compounds; and (f) irrigating a golf course area with reclaimed water which has been processed in accordance with the preceding steps; wherein said predetermined acceptable ranges are set within the following ranges: (i) for total organic carbon compounds, 0 milligrams per liter to 50 milligrams per liter; (ii) for residual chlorine, 0 milligrams per liter to 1 milligrams per liter; (iii) for pH, 6 to 8; (iv) for chloride compounds, 0 milligrams per liter to 70 milligrams per liter; and, (v) for sodium, 0 milligrams per liter to 70 milligrams per liter.
 10. The process of claim 9 wherein said plurality of monitors includes at least one additional monitor to obtain test results selected from the group consisting of the following water quality characteristics: (vi) hardness; (vii) turbidity; (viii) alkalinity; and (ix) conductivity.
 11. The process of claim 10 wherein said plurality of monitors includes additional monitors to obtain test results for the following water quality characteristics: (j) hardness; (k) turbidity; (l) alkalinity; and (m) conductivity.
 12. The process of claim 9 wherein said providing feedback to show any water quality characteristic deviation includes initiating an alarm selected from the group consisting of audio alarms, visual alarms and combinations thereof.
 13. The process of claim 12 wherein said alarm is initiated in response to feedback showing any deviation from water quality characteristics selected from the group consisting of pH, chloride compounds and sodium.
 14. The process of claim 10 wherein said providing feedback to show any water quality characteristic deviation includes initiating an alarm selected from the group consisting of audio alarms, visual alarms and combinations thereof.
 15. The process of claim 14 wherein said alarm is initiated in response to feedback showing any deviation from water quality characteristics selected from the group consisting of pH, chloride compounds, sodium, hardness, turbidity, alkalinity and conductivity.
 16. The process of claim 9 wherein said dechlorination system is a vitamin C dechlorination system wherein vitamin C is fed into said reclaimed water in response to said computerized data handling system showing a deviation from said predetermined acceptable range for active chlorine.
 17. The process of claim 10 wherein said predetermined acceptable ranges for the following water quality characteristics are set within the following ranges: (vi) for hardness, 0 to 200 milligrams of calcium carbonate per liter; (vii) for turbidity, 0 to 10 nephelometric turbidity units; (viii) for alkalinity, 0 to 200 milligrams per liter total alkalinity; and (ix) for conductivity, o to 4000 microSiemens per centimeter.
 18. The process of claim 11 wherein said predetermined acceptable ranges for the following water quality characteristics are set within the following ranges: (vi) for hardness, 0 to 200 milligrams of calcium carbonate per liter; (vii) for turbidity, 0 to 10 nephelometric turbidity units; (viii) for alkalinity, 0 to 200 milligrams per liter total alkalinity; and (ix) for conductivity, o to 4000 microSiemens per centimeter.
 19. The process of claim 9 wherein said plurality of monitors includes a nitrate monitor.
 20. The process of claim 19 wherein predetermined acceptable ranges for nitrate are set within the range of 0 to 100 milligrams per liter nitrate as nitrogen. 